KR102386288B1 - Honeycomb ceramic heater - Google Patents

Abstract

The present invention relates to a honeycomb ceramic heater capable of increasing heat generation efficiency. According to the present invention, the honeycomb ceramic heater includes: a ceramic body including a ceramic body at a center position and a ceramic body at a side position; an upper electrode; and a lower electrode.

Description

Honeycomb ceramic heater {Honeycomb ceramic heater}

The present invention relates to a honeycomb ceramic heater, and more particularly, the upper and lower electrodes do not interfere with each vent hole of the ceramic body at all, the heating area is expanded, and when using several heaters, it is necessary to connect the lead-in wires individually for each heater The present invention relates to a honeycomb ceramic heater in which there is no air gap, the support force of the ceramic body is improved by the upper and lower electrodes, and the electric current can flow evenly throughout the ceramic body.

In general, heaters used in hair dryers, hot air blowers, instantaneous water heaters, cold and hot water machines, dryers for washing machines, gas ranges, boilers, etc. are mainly in the form of metal coils or plates. However, these metal heaters not only have poor heat exchange thermal efficiency due to heat dissipation, but also have short lifespan due to deterioration of durability due to weakening of corrosion resistance, generate a large amount of electromagnetic waves, and consume a lot of power.

Accordingly, in recent years, the use of silicon carbide non-oxide-based ceramic heaters is increasing, and silicon carbide (SiC) non-oxide-based ceramic heaters have excellent heat resistance and thermal conductivity and are widely used as heater materials. However, since silicon carbide has low water resistance and is easily deteriorated upon contact with moisture and loses its function as a heater, an appropriate selection of applied articles is required.

1 is a photograph showing an example of a conventional honeycomb ceramic heater, the configuration of which is a cylindrical ceramic heating body 2, and a first electrode plate made of metal on the upper and lower surfaces of the ceramic heating body 2 (4) and the second electrode plate (5) are in contact to supply current to the ceramic heating body (2). In addition, the first electrode plate 4 and the second electrode plate 5 further include a first bracket 6 and a second bracket 7, respectively, and the first bracket 6 and the second bracket 7 ) are electrically connected by four connecting bolts (8).

However, in this conventional honeycomb ceramic heater, the first bracket 6 and the second bracket 7 block the upper and lower vent holes 9 of the ceramic heating body 2, and the first electrode plate 4 And as the current between the first bracket 6 and the second bracket 7 connected to the second electrode plate 5 directly flows through the heating film on the surface of the vent 9, an impact such as an arc phenomenon is applied to each When the heating film on the surface of the vent hole 9 is applied, the heating film of each vent hole 9 of the ceramic heating element 2 is ruptured or damaged.

1. Republic of Korea Public Utility Model No. 20-2019-0002226 (published on 2019.09.04.)

Accordingly, the present invention was devised to solve the problems of the related art as described above, and its purpose is that the upper and lower electrodes do not interfere with each vent hole of the ceramic body at all, the heating area is expanded, and multiple heaters can be used. An object of the present invention is to provide a honeycomb ceramic heater that eliminates the need to individually connect incoming wires for each heater, improves the bearing capacity of the ceramic body by the upper and lower electrodes, and allows electric current to flow evenly throughout the ceramic body.

One form of a ceramic heater according to the present invention for achieving the object of the present invention is composed of a center position ceramic body and a side position ceramic body having a plurality of ventilation holes, and the side position ceramic body is a center position ceramic body a ceramic body having an insertion hole corresponding to , a connection passage having no ventilation hole formed between the insertion hole and the side position ceramic body, and a plurality of ceramic bolt through holes formed outside the side position ceramic body;

It is formed of a band-shaped upper electrode side support frame formed along the outer periphery of the side position ceramic body, and the upper electrode side support frame has a shape corresponding to the center position ceramic body inside to support the upper electrode side without interfering with the vent hole. It has an upper electrode center support frame integrally formed with a frame, an upper electrode plate spring is interposed between the upper electrode sensor support frame and the center position ceramic, and the upper electrode side support frame passes through the ceramic bolt of the side position ceramic body an upper electrode including a plurality of upper electrode bolt fastening holes corresponding to the balls;

It is formed of a band-shaped lower electrode side support frame formed along the outer periphery of the side position ceramic body, and the lower electrode side support frame has a shape corresponding to the center position ceramic body therein to support the lower electrode side without interference of the vent hole. It has a lower electrode center support frame integrally formed in a frame, an upper electrode plate spring is interposed between the lower electrode center support frame and the center position ceramic, and the lower electrode side support frame passes through the ceramic bolt of the side position ceramic body and a lower electrode including a plurality of lower electrode bolt fastening holes corresponding to the balls.

As described above, in the present invention, the ceramic body is divided into a center position ceramic body and a side position ceramic body, and the center position ceramic body and the side position ceramic body are formed without the upper and lower electrodes interfering with each vent hole of the ceramic body. By connecting them to each other, there is no rupture or damage to the heating film of the vents due to an impact such as an arc phenomenon caused by the existing upper and lower electrodes interfering with each vent of the ceramic body. In addition to being able to prevent the shortening of the lifespan of the ceramic heater due to damage and damage, the heating area is rather expanded, and when multiple heaters are used, there is no need to connect the lead-in wires individually to each heater, so It is possible to organize the surrounding environment of the heater module in a more orderly state due to the cluttered multi-stranded lead-in wires, as well as the convenience, and the bearing capacity of the ceramic body is improved by the upper and lower electrodes, and the current flows through the entire ceramic body. By being able to flow evenly, it has the effect of further increasing the performance and reliability of the ceramic heater as well as the increase of the heating efficiency and the continuity of the ceramic heater structure.

1 is a photograph showing the overall structure of a conventional honeycomb ceramic heater.
2 to 4 show an embodiment of a honeycomb ceramic heater according to the present invention,
2 is a perspective view.
Figure 3 is an exploded perspective view of Figure 2;
Fig. 4 is a cross-sectional view of Fig. 2;
5 to 7 show another embodiment of the honeycomb ceramic heater according to the present invention,
5 is a perspective view.
Figure 6 is an exploded perspective view of Figure 5;
Fig. 7 is a cross-sectional view of Fig. 5;

Advantages and features of embodiments of the present invention, and methods of achieving them, will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the embodiments of the present invention, which may vary depending on the intention or custom of the user or operator. Therefore, the definition should be made based on the content throughout this specification.

Hereinafter, a honeycomb ceramic heater according to the present invention will be described in detail with reference to the accompanying drawings.

2 to 4 show an embodiment of a honeycomb ceramic heater according to the present invention, in which FIG. 2 is a perspective view, FIG. 3 is an exploded perspective view of FIG. 2, and FIG. 4 is a cross-sectional view of FIG. Likewise, the honeycomb ceramic heater according to the present invention includes a ceramic body 100 having a plurality of vent holes 100A having a heating film on the surface thereof, and upper and lower electrodes 200 respectively provided on the upper and lower portions of the ceramic body 100 . ) 300 , and the upper and lower electrodes 200 and 300 are connected to each other with bolts B to allow electricity to flow.

More specifically, the ceramic body 100 has a circular center position ceramic body 100 and a side position having insertion holes 121A and 121B having corresponding diameters of the center position ceramic body 110 . The ceramic body 120 is separated and the center position ceramic body 110 is inserted into the insertion holes 121A and 121B. At this time, the center position ceramic body 110 is formed to have a greater thickness than the side position ceramic body 120 and is provided to slightly protrude upward and downward of the insertion holes 121A and 121B. And, between the insertion holes (121A) and (121B) and the side position ceramic body 120, the vent hole (100A) is not formed connection passages (123A, 123B) are formed, the side position ceramic body (120) A plurality of ceramic bolt through-holes (122A, 122B) are formed on the outside.

Here, in one embodiment of the present invention, the center position body 110 is formed as a circular center position body 110A, and the side position ceramic body 120 is formed as a square side position ceramic body 120A, When a plurality of ceramic heaters are provided in parallel to form a single module, they can be closely connected to each other without an empty space between the ceramic heaters, so that more ceramic heaters can be provided within a predetermined area. And, the connection passage 123A is formed in a straight line between the insertion hole 121A and each edge of the side position ceramic body 120A, and each connection passage 123A is a ceramic bolt through hole 122A and A ceramic electrode connection hole 124A is formed.

The upper electrode 200 supports a band-shaped upper electrode side support frame 210 formed along the outer edge of the side position ceramic body 120 and an upper electrode center located at the center of the upper electrode side support frame 210 . As composed of a frame 220, in one embodiment of the present invention, the upper electrode side support frame 210 is formed as a square upper electrode side support frame 210A corresponding to the side position ceramic body 120, , The upper electrode side support frame 210A and the upper electrode center support frame 220A are integrally connected to each other by a connecting piece 230 having a shape corresponding to the connecting passage 123A of the side position ceramic body 120A. The connecting piece 230 has an upper electrode bolt fastening hole 231 and an upper electrode electrode connecting hole 232 corresponding to the ceramic bolt through hole 122A and the ceramic electrode connecting hole 124A.

The lower electrode 300 is the same as the upper electrode 200 symmetrically to face each other. Like the upper electrode 200, the lower electrode side supports the lower electrode in the form of a band formed along the periphery of the side position ceramic body 120A. It is composed of a frame 310 and a lower electrode center support frame 320 positioned at the center of the lower electrode side support frame 310 . At this time, the lower electrode side support frame 310 is formed in a square shape corresponding to the side position ceramic body 120A, and the side position ceramic frame 310A and the lower electrode center support frame 320A are disposed between the lower electrode side support frame 310A and the lower electrode center support frame 320A. They are integrally connected to each other by a connecting piece 330 having a shape corresponding to the connecting passage 123A of the body 120A, and the connecting piece 330 is a ceramic bolt through hole 122A and a ceramic electrode connecting hole 124A. It has a corresponding lower electrode bolt fastening hole 331 and a lower electrode electrode connecting hole 332 . Here, unexplained reference numerals B are 250 and 350, upper and lower electrode plate springs for increasing the adhesion between the upper and lower electrodes 200 and 300 and the center position ceramic body 110A, B is a bolt, N is a nut, and W is an insert washer to increase the fastening force and adhesion of the bolt ( ).

In addition, the upper electrode center support frame 220A and the lower electrode center support frame 320A have upper electrode bending jaws 221A and lower electrode bending jaws 321A, respectively, along inner sides. The upper electrode bending jaw 221A and the lower electrode bending jaw 321A support upper and lower protrusions of the center position ceramic body 110A inserted into the insertion hole 121A of the side position ceramic body 120A described above. to allow current to be conducted evenly along the perimeter of the center position ceramic body 110A.

In the present invention configured as described above, first, the upper electrode 200 is covered with the upper electrode plate spring 250 on the side position ceramic body 120A, and the center position ceramic body 110A is inserted into the side position ceramic body 120A Insert the ball (121A) from the lower side to the upper side. Then, the lower electrode 300 is attached to the lower part of the center position ceramic body 110A and the side position ceramic body 120A together with the lower electrode plate spring 350, and then the bolt (B) is screwed with the insert washer (W). Together with the upper electrode bolt fastening hole 231, the ceramic bolt through hole 122A, and the lower electrode bolt fastening hole 331, the assembly is completed by fastening them together with the insert washer (W) with the nut (N). .

In this state, the upper and lower electrodes 200 and 300 are energized by flowing (+) and (-) currents, respectively. At this time, the upper and lower electrodes 200 and 300 are electrically connected to each other by a volt (B). Since they are connected, there is no need to separately connect wires to the upper and lower electrodes 200 and 300 . Accordingly, the center position ceramic body 110A and the side position ceramic body 120A are heated by electrical resistance to generate heat through the vent hole 100A. At this time, the vent hole 100A of the center position ceramic body 110A and Since heat is also generated through the ventilation holes 100A of the side position ceramic body 120A, the heating efficiency can be further increased, and the upper and lower electrode bending jaws formed in the upper and lower electrode center support frames 220A and 320A. (221A) (321A) has the advantage that occurs evenly over the entire ceramic body 100 without being biased by the heat generation. In addition, since the upper and lower electrodes 200 and 300 do not interfere at all with the vents 100A formed in the ceramic body 100, shocks such as arcing caused by the existing upper and lower electrodes interfering with the vents of the ceramic body As there is no rupture or damage to the heating film of the vent by the ventilator, it is possible to prevent shortening of the life of the heater due to rupture and damage to the heating film of the vent, as well as to further increase the performance and reliability of the heater.

5 to 7 are views showing another embodiment of the honeycomb ceramic heater according to the present invention. FIG. 5 is a perspective view, FIG. 6 is an exploded perspective view of FIG. 5, and FIG. 7 is a cross-sectional view of FIG.

Here, the feature is that the ceramic body 100 is separated into three circular center position bodies 110B and circular side position ceramic bodies 120B, and the three center positions are placed on the side position ceramic body 120B. Three insertion holes 121B are formed to correspond to the ceramic body 110B, and these three insertion holes 121B are configured to form a triangular shape at equal intervals as a whole. In addition, the upper and lower electrode side support frames 210B and 310B are formed in a circular shape to correspond to the side position ceramic body 120B, and there are three upper and lower electrode side support frames 210B and 310B inside the upper and lower electrode side support frames 210B and 310B. .Lower electrode center support frames 220B and 320B are provided, wherein one side of the upper and lower electrode center support frames 220B and 320B is integrally formed with the upper and lower electrode side support frames 210B and 310B. and the other side of the upper and lower electrode center support frames 220B and 320B are integrated with each other by upper and lower electrode center support pieces 220B and 320B having upper and lower electrode bolt fastening holes 231 and 331 It is characterized in that it is configured to be formed as At this time, the upper and lower electrode center support pieces 220B and 320B have upper and lower electrode bending jaws 221B and 321B along the inner surface as in the embodiment of the present invention. And since the assembly process and operation of the other embodiments of the present invention are the same as those of one embodiment of the present invention, detailed descriptions will be omitted to avoid duplication. However, in another embodiment of the present invention, there are three center position ceramic bodies that are the main sources of heat generation, so as in one embodiment of the present invention, there is an advantage of being able to output a greater output than the heater of a single center position ceramic body. .

In this way, the present invention separates the ceramic body into a center position ceramic body and a side position ceramic body, so that the center position ceramic body and the side position ceramic body are connected to each other without the upper and lower electrodes interfering with each vent hole of the ceramic body. By doing so, there is no rupture or damage to the heating film of the vents due to an impact such as an arc phenomenon caused by the interfering of the vents of the ceramic body by the upper and lower electrodes in the past. It is possible to prevent the shortening of the lifespan of the ceramic heater according to It is possible to organize the surrounding environment of the heater module in a more orderly state due to the cluttered and scattered lead-in wires. As a result, it is possible to further increase the performance and reliability of the ceramic heater as well as increase the heating efficiency and the continuity of the ceramic heater structure.

In the above, the honeycomb ceramic heater according to the present invention has been specifically described, but this is only a description of the most preferred embodiment of the present invention, and the present invention is not limited thereto, and the scope is determined by the appended claims. is limited In addition, it will be clear that any person skilled in the art will be able to make various modifications and imitations according to the description of the specification of the present invention, but this also does not depart from the scope of the present invention.

100: ceramic body
100A: vent 110,110A,110B: center position ceramic body
120, 120A, 120B: Side position ceramic body 121A, 121B: Insert hole
122A, 122B: Ceramic bolt through hole 123A, 123B: Connection passage
124A, 124B: ceramic electrode connector
200: upper electrode
210, 210A, 210B: upper electrode side support frame
220, 220A, 220B: upper electrode center support frame
221A, 221B: upper electrode bending jaw 230: connecting piece
231: upper electrode bolt fastening hole 232: upper electrode electrode connection hole
240: upper electrode center support piece 250: upper electrode plate spring
300: lower electrode
310, 310A, 310B: lower electrode side support frame
320, 320A, 320B: lower electrode center support frame
321A, 321B: lower electrode bending jaw 330: connecting piece
331: lower electrode bolt fastening hole 332: lower electrode electrode connection hole
340: lower electrode center support piece 350: lower electrode plate spring

Claims (3)

The center position ceramic body 110 and the side position ceramic body 120 having a plurality of vent holes 100A are separately configured, and the side position ceramic body 120 has an insertion hole corresponding to the center position ceramic body 110 . (121A) and (121B), and between the insertion holes (121A, 121B) and the side position ceramic body 120, the connection passages (123A) and (123B) without the ventilation hole (100A) are formed, the side a ceramic body 100 in which a plurality of ceramic bolt through holes 122A and 122B are formed on the outside of the position ceramic body 120;
It is formed of a band-shaped upper electrode side support frame 210 formed along the periphery of the side position ceramic body 120 , and the upper electrode side support frame 210 has a shape corresponding to the center position ceramic body 110 therein. has the upper electrode center support frame 220 integrally formed with the upper electrode side support frame 210 without interference of the vent hole 100A, and the upper electrode center support frame 220 and the center position ceramic 110 An upper electrode plate spring 250 is interposed between an upper electrode 200 including a bolt fastening hole 231;
It is formed of a band-shaped lower electrode side support frame 310 along the outer edge of the side position ceramic body 120 , and the lower electrode side support frame 310 has a shape corresponding to the center position ceramic body 110 therein. has a lower electrode center support frame 320 integrally formed with the lower electrode side support frame 310 without interference of the vent hole 100A, and the lower electrode center support frame 320 and the center position ceramic body 110 ) is interposed between the upper electrode plate spring 250 , and the lower electrode side support frame 310 has a plurality of lower portions corresponding to the ceramic bolt through holes 122A and 122B of the side position ceramic body 120 . A honeycomb ceramic heater comprising: a lower electrode (300) including an electrode bolt fastening hole (331).
According to claim 1,
The ceramic body 100 is divided into a circular center position body 110A and a rectangular side position ceramic body 120A, and the side position ceramic body 120A is inserted corresponding to the center position ceramic body 110A. A connection passage 123A having a hole 121A and without a ventilation hole 100A is formed between the insertion hole 121A and the side position ceramic body 120A, and a ceramic bolt is penetrated through the connection passage 123A. What is configured to have a ball (122A) and a ceramic electrode connection hole (124A);
The upper electrode side support frame 210 is formed as a rectangular upper electrode side support frame 210A corresponding to the side position ceramic body 120A, and the upper electrode side support frame 210A and the upper electrode center are supported. The frame 220A is formed to be integrally connected by a connecting piece 230 having a shape corresponding to the connection passage 123A and an upper electrode bolt fastening hole 231 and an upper electrode electrode connecting hole 232;
The lower electrode side support frame 310 is formed as a rectangular lower electrode side support frame 310A corresponding to the side position ceramic body 120A, and the lower electrode side support frame 310A and the lower electrode center are supported. The frame 320A is integrally connected by a connecting piece 330 having a shape corresponding to the connecting passage 123A and a lower electrode bolt fastening hole 331 and a lower electrode electrode connecting hole 332 between the frame 320A. Honeycomb ceramic heater.
According to claim 1,
The ceramic body 100 is separately composed of three circular center position body 110B and circular side position ceramic body 120B, and the side position ceramic body 120B includes the three center position ceramic bodies ( 110B) and the three insertion holes (121B) corresponding to the whole to form an equally spaced triangular shape;
The upper electrode side support frame 210 is formed as a circular upper electrode side support frame 210B corresponding to the side position ceramic body 120B, and the upper electrode center support frame 220B has the three center positions. It consists of three upper electrode center support frames 220B to correspond to the ceramic body 110B, wherein one side of the upper electrode center support frame 220B is integrally formed with the upper electrode side support frame 210B, and the other side is the upper part. What is configured to be integrally formed with each other by the upper electrode center support piece 240 having the electrode bolt fastening hole 231;
The lower electrode side support frame 310 is formed as a circular lower electrode side support frame 310B corresponding to the side position ceramic body 120B, and the lower electrode center support frame 320B has the three center positions. It consists of three lower electrode center support frames 320B to correspond to the ceramic body 110B, wherein one side of the lower electrode center support frame 320B is integrally formed with the lower electrode side support frame 310B and the other side is the lower part. A honeycomb ceramic heater, characterized in that it is formed integrally with each other by a lower electrode center support piece (340) having an electrode bolt fastening hole (331).

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